RU2269621C1 - Method for fish attracting into inlet head of fish passing and spawning channel and fish passing and spawning channel - Google Patents

Abstract

FIELD: hydraulic building, particularly fish passes to permit fish passage through support structures to fish hatchery and growth areas.

SUBSTANCE: fish passing and spawning channel comprises waterway made as a channel and with head part connected to upper pool and mouth part communicated with lower pool of hydrosystem, rough members made as parallelepipeds located on channel bottom along the full length thereof and extending at acute angle to longitudinal channel axis. The channel also has additional feeding unit with inlet part connected with upper pool and outlet part communicated with head part. Outlet part of additional feeding unit is made as a tray parallel to longitudinal axis of inlet head and outlet orifices thereof are located directly in additional feeding unit tray. Waterway and tray of additional feeding unit are spaced with partition wall extending for the full flow depth. Bottom of additional feeding unit tray is stepped and inclined towards lower pool side. Outlet orifices are arranged in beginning of each step. Inlet part of additional feeding unit is made as pressure pipeline provided with flow regulator. End part of additional feeding unit tray is freely communicated with waterway interior and initial part thereof is provided with jet guiding wall extending at an angle to through river flow. Inlet head has additional outlet orifice arranged from outer surface of jet guiding wall and arranged in surface horizon in parallel to guiding wall plane. The orifice is communicated with pressure pipeline. Initial waterway part located upstream from head part is provided with the second stage of additional feeding unit. Additional flow, which was earlier supplied in head part, is transferred directly to waterway section located upstream from inlet head to stimulate direct fish passage into waterway. After stabilization of fish-attractive flow borders and fish-attractive conditions, which stimulate fish passage in head pool additional water flow is supplied directly to waterway part located upstream from head part and at the same time additional flow supply in head part is stopped.

EFFECT: increased efficiency of fish passage in the channel.

25 cl, 56 dwg

Description

The invention relates to hydraulic engineering, in particular to fish passage facilities designed to allow fish producers to pass through retaining structures to spawning and feeding grounds.

There is a method of attracting fish to the inlet head of the fish-spawning channel [1], which consists in creating a fish attracting stream in the inlet of the inlet head by supplying an attracting flow from the water supply path and additional water supply paths to the inlet head, and a stable hydraulic structure is formed in the influence zone of the inlet head and against the background of the search zone for fish.

The disadvantage of this method is the low efficiency of attracting fish to the inlet head and the irrational use of water resources.

The closest technological scheme is the method of attracting fish to the inlet head of the fish-spawning channel [2], which consists in creating a fish attracting stream in the inlet of the inlet head by supplying an attractive flow from the water supply path and an additional power supply to the inlet head, while forming a stable hydraulic structure in the zone of influence of the input head and against the background of the search zone for fish.

The disadvantage of this method is the low efficiency of attracting fish to the fish passage tract of the channel and the irrational use of additional water flow.

Known fish passage and spawning channel [1], including a water path made in the form of a channel, the head part of which is connected to the upper pool of the hydraulic system, and the mouth part is connected to the lower pool, elements of enhanced and natural roughness installed on the bottom of the channel along its length and additional flow paths, the head parts of which are connected to the water supply path, while additional flow paths are made with different longitudinal slopes.

The disadvantage of this structure is the low efficiency of the allocation of attracting fish flow generated in the inlet head.

The closest in technical essence and the achieved result is a fish-spawning channel [2], including a water supply path made in the form of a channel, the output head of which is connected to the upper pool of the waterworks, and the input head - to the lower pool, elements of enhanced roughness, made in the form parallelepipeds mounted on the bottom of the channel along its length at an acute angle to the longitudinal axis of the channel and an additional power supply unit, the input part of which is connected to the upper pool, and the output part with the input head, When this output of the auxiliary power unit is designed as a tray, disposed parallel to the longitudinal axis of the input tip, and its outlet openings are arranged directly in the tray for additional power supply unit, and feeding canal tract and additional power supply tray are separated from each other by a partition wall.

The disadvantage of this method is the low efficiency of attracting fish to the fish passage tract of the channel and the irrational use of additional water flow.

The aim of the invention is the creation of effective hydraulic conditions in a fish-spawning channel for the passage of fish into its internal space.

The invention consists in the following.

According to claim 1 of the claims. The technology of transferring the additional flow rate previously supplied to the inlet head directly to the section of the water supply path of the fish-spawning channel located upstream of the inlet head allows provoking fish concentrated in front of the inlet head to actively enter directly into the inner space of the fish passage path. This operation increases the efficiency of the entire structure. Its essence is as follows.

After the process of stabilizing the boundaries of the fish attracting stream and the conditions for fish to enter the inlet head, the additional water flow is fed directly to the section of the water supply path located upstream of the inlet head, while at the same time, the additional flow to the inlet head is cut off.

According to claim 2 of the claims. The supply of additional water flow to the surface of the water mirror allows you to create the most favorable hydraulic conditions for the passage of bottom fish species (for example, sturgeon). At the same time, in the bottom horizons of the flow, the influence of additional masses of flow is almost not felt. In addition, the noise of the water flow incident on the surface of the mirror imitates conditions close to the operating conditions of the spillway dam of the waterworks. Moreover, additional water falling on the surface of the flow mirror allows aeration of the surface layers of the water stream.

According to claim 3 of the claims. The supply of an additional flow rate of water to the surface horizons of the fish passage tract allows providing normal conditions for the merging of two expenditures - the main (flow passage of the fish passage) and additional (flow from an additional power supply). At the same time, in the bottom horizons of the main flow there is practically no effect of additional masses of discharge discharged to the surface horizons of the flow.

According to claim 4 of the claims. The additional flow of water in the form of dispersed hydraulic jets, oriented at an angle to the longitudinal axis of the water supply path, reduces the hydraulic resistance of the main stream and reduces the likelihood of erosion of the bed of the fish-spawning channel.

According to claim 5, claims. The additional flow of water in the form of dispersed hydraulic jets oriented parallel to the longitudinal axis of the water supply path also reduces the hydraulic resistance of the main stream and reduces the likelihood of erosion of the bed of the fish-spawning channel. In addition, this pattern of discharge of the additional flow of water does not disorient the fish as they move along the fish passage.

According to claim 6, claims. The supply of additional water flow into the thickness of the fish passage tract allows us to provide normal conditions for the merger of two costs - the main (flow fish passage) and additional (flow from an additional power supply). At the same time, in the thickness of the stream, the average velocity of the main stream increases, which makes it possible to activate the movement of fish moving in these horizons.

According to claim 7 of the claims. The supply of additional water flow to the bottom horizons of the fish passage tract flow also allows us to provide normal conditions for the merger of two expenses - the main (flow of the fish passage) and additional (flow from an additional power supply). At the same time, the average velocity of the main stream increases in the bottom horizons of the stream, which makes it possible to activate the movement of fish moving in these horizons (for example, sturgeons).

According to claim 8 of the claims. The flow diagram of the additional flow of water in the direction of the main stream in the water supply path is an option for dumping additional masses of water. In this embodiment, the main stream minimally experiences resistance from the side of the additionally discharged flow. In this case, the velocity values in the vertical and planned diagrams only increase.

According to claim 9, the claims. The flow of additional water flow against the direction of the main stream in the water supply path is an alternative option for dumping additional masses of water. In this embodiment, the main stream experiences hydraulic resistance in those horizons of the stream into which the discharge of additional water flow is performed. In this case, the velocity values in the vertical and planned diagrams in the discharged alignments decrease. The application of this scheme is possible if it is necessary to create additional water level backwater in the initial part of the fish passage-spawning channel or to create favorable hydraulic conditions for the passage of fish in various horizons of the water passage of the fish passage channel.

According to claim 10 of the claims. The implementation of the separation wall to the entire depth of the stream allows you to create an autonomous channel in the structure of the inlet head, while this channel is designed to form an additional stream that attracts fish, but also allows fish to move freely from the downstream side in the direction of the fish passage tract of the spawning and spawning channel.

The execution of the bottom of the tray of the additional power supply unit is stepped with a slope towards the downstream side, while the outlet openings of the additional power supply unit are located at the beginning of each stage, which makes it possible to obtain the layout of the additional power supply unit, the main part of the flow rate of which is supplied and concentrated in the bottom horizons of the water flow. This arrangement is aimed at creating a powerful fish attracting stream in the bottom horizons, which meets the optimal conditions for attracting bottom fish species (for example, sturgeon), for which this fish passage structure is intended.

The implementation of the supply part of the additional power supply in the form of a pressure pipe equipped with a flow regulator allows without any intermediate loss of flow to guarantee the supply of the working flow to the outlet openings of the additional power supply. In addition, the pressure pipe fits optimally into the devices and structures of the waterworks system, is easy to operate, easy to install during construction, and, in addition, in case of flood events on the river, it is less susceptible to the dynamic influence of the water stream and practically eliminates the entry of its water-carrying part by entrained sediment floating debris and sand, which are always present in the water masses of flood discharge.

The implementation of the initial part of the tray of the additional power supply unit equipped with a directional wall installed at an angle to the transit stream of the river makes it possible to more fully use the kinetic energy of the transit water stream, which when it runs onto the plane of the directional wall experiences resistance from this artificial obstacle and deviates in the direction of the river channel. In this case, the external (from the upstream side) border of the stream attracting the fish is formed.

To increase the efficiency of distinguishing the external boundary (the range of its distribution in the river channel), as well as to enhance its effect on the water masses of the river, the inlet head is equipped with an additional outlet located on the side of the outer surface of the directional wall, which is located in the surface horizon of the stream and parallel to its plane moreover, the outlet is connected to the pressure pipe. When a working flow of water is supplied from the pressure pipe from the outlet, a plane-parallel hydraulic jet flows, which at the initial stage of its propagation moves along the outer surface of the flow guide wall. This scheme of supplying an additional water flow rate allows, due to the dynamic effect of a plane-parallel hydraulic jet on the river flow, as well as due to the active ejection of the surrounding water masses, to increase not only the propagation range of the fenders, but also helps to create stable conditions for the formation of the outer boundary of the flow that attracts fish.

Let us explain in more detail the last conclusion. The external border of the fish attracting stream is dynamically influenced (pressure) by water masses discharged through spillways of the spillway dam of the waterworks. In this case, depending on the nature of the discharge (uniform discharge mode through the hydraulic system or not), the average speed of the river’s transit water flow, and also depending on the speed of the jet flowing from the additional outlet, and the angle of the jet forming retaining wall, the coordinates of the outer boundary of the attracting fish currents will be different. As is known from the hydraulics of the water flow, the maximum resistance to the transit flow is created by an artificial barrier installed at an angle of 90 °, and accordingly (which, incidentally, is logical) a bump (secondary, flow characterized by the maximum coordinates of its outer boundary is formed. However, taking into account the scheme layout of the inlet head, hydrological conditions in the downstream, as well as conditions for ensuring the indelibility of the bottom of the river channel (formation of a washout funnel in the immediate vicinity of the inlet Application), the authors propose to use potokoformiruyuschuyu hydraulic jet which extends in a cocurrent flow of the river at an acute angle in the surface layer flow transit.

The implementation of the initial section of the water supply path, located upstream from the inlet head, equipped with a second stage of an additional power supply, allows you to implement the attraction technology according to the method for which the authors of the invention have claims (see paragraphs 1-9 of the present claims).

Since the technical solution of the output head of the additional second-stage power supply unit may be different, the authors considered it appropriate (necessary and sufficient) to indicate the general wording (characteristic) of this distinguishing feature. This allows us to expand the range of legal validity of the patent, and also closes the possible paths for our opponents to block the desired range of action of the authors.

The technology of transferring additional water flow from one branch of the supply part to another of its branch is as follows.

After the process of stabilizing the boundaries of the fish attracting stream and the conditions for the fish to enter the inlet head, an additional flow of water is fed directly to the section of the water supply path located upstream of the inlet head, while at the same time the supply of additional flow to the inlet head is stopped. This technology of transferring the additional flow rate previously supplied to the inlet head directly to the section of the water supply tract of the fish-spawning channel located upstream of the inlet head allows provoking the fish concentrated in front of the inlet head to actively enter directly into the inner space of the fish passage channel.

According to claim 11, the claims. The execution of the second stage of the additional power supply in the form of perforated pipelines placed across the water supply path allows you to apply additional water flow to the surface of the water mirror. In this case, the most favorable hydraulic conditions are created for the passage of bottom fish species (for example, sturgeon). In addition, in the bottom horizons of the flow practically no effect of additional mass flow. In addition, the noise of a water stream incident on the surface of a mirror imitates conditions close to the operating conditions of a spillway dam of a waterworks. Moreover, additional water falling on the surface of the flow mirror allows aeration of the surface layers of the water flow and saturates the water with additional oxygen.

According to paragraph 12 of the claims. The perforation of the perforated pipelines, oriented at an acute angle to the surface of the water, makes it possible to actively aerate the surface layer of the flow, since dispersed hydraulic jets actively inject air surrounding themselves and draw it into the surface horizons of the stream. With this arrangement, the acoustic effect arising from the interaction of the jets with the surface of the water is more pronounced.

According to item 13 of the claims. The perforation of the perforated pipelines, oriented at an obtuse angle to the surface of the water, also allows you to aerate the surface layer of the stream, since falling water droplets contribute to the process of saturation of the surface horizons of the air. However, in this arrangement there are no concentrated jets (streams), which avoids the concentration of surface fish in the discharge zone of the additional flow.

According to claim 14. The implementation of the input head with fish-guiding devices in the form of bottom thresholds, while the thresholds are curved in plan and their convex side facing the dividing wall, allows not only to stabilize the flow of fish attracting fish in the bottom horizons, but also allows the formation of stable tactile landmarks using which bottom species fish (for example, sturgeon) are guaranteed to move in the direction of the fish passage.

According to clause 15 of the claims. The fulfillment of the height of the bottom rapids, decreasing in the direction of the downstream, allows you to enhance the effect of stabilization of the flow in the bottom horizons and, in addition, gives the fish the opportunity to move in the space limited by the bottom rapids, thereby changing the paths of their movements.

According to clause 16 of the claims. The execution of the end parts of the bottom sills, located in different transverse sections laid out in the river bed, allows you to create tactile landmarks along the length of the bottom sills. This arrangement allows you to intercept bottom fish at an early stage of their movement in the zone of influence of fish-guiding devices.

According to claim 17. The implementation of the separation wall is curved in plan, with its convex surface facing the upstream, allows you to optimize the hydraulic conditions in the zone of influence of the inlet head, as well as improve the conditions for the movement of fish in the direction of the fish passage. In addition, the curved plane of the dividing wall makes it possible to provide a continuous flow around the river on its outer side surface.

According to claim 18. The execution of the guide wall parallel to the separation wall allows you to optimize the hydraulic structure of the fish attracting stream and the conditions for the promotion of fish in the area of their installation.

According to claim 19 of the claims. The execution of the distributing part of the perforated pipelines with the possibility of rotation by means of a drive around its horizontal axis allows you to quickly change the discharge pattern of the additional flow of water to the surface of the water mirror (for example, the transition from the scheme "perforation holes are oriented at an acute angle to the water surface" to the scheme "perforation holes are oriented under obtuse angle to the surface of the water "and vice versa).

According to claim 20 of the claims. The second stage of the additional power supply in the form of perforated pipelines placed along the water supply path is an option to install the output head of the additional power supply.

According to claim 21. The execution of the distributing part of the perforated pipelines with the possibility of rotation by means of a drive around its horizontal axis allows you to quickly change the discharge pattern of the additional flow of water to the surface of the water mirror (for example, the transition from the scheme "perforation holes are oriented at an acute angle to the water surface" to the scheme "perforation holes are oriented under obtuse angle to the surface of the water "and vice versa).

According to claim 21. Mechanical drive rotation of the distributing part of the perforated pipelines is an embodiment of the drive. In addition, a mechanical drive is more reliable than all other types of drive mechanisms.

According to claim 23 of the claims. The execution of the drive rotation of the distributing part of the perforated pipelines hydraulic is also an option for the design of the drive. However, in this case, we are able to use the kinetic energy of the water stream supplied to the perforated pipelines.

According to paragraph 24 of the claims. The implementation of the rotation drive of the distributing part of the perforated pipelines in the form of an impeller rigidly connected to the distributing part and installed in the end part of the supply pipe is a special case of a hydraulic drive.

According to claim 25 of the claims. Fulfillment of sections of the interface of the steps of the tray of the additional power supply unit in the form of planes inclined towards the downstream side allows optimizing the process of movement of bottom fish in the bottom of the autonomous tray.

The solution to this problem is achieved by implementing a new method of attracting fish to the input head of the fish-spawning channel and creating a new design of the fish-spawning channel that implements it. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - input head of the fish-spawning channel, plan;

figure 2 is the same, an option of the second stage of an additional power supply;

figure 3 is a variant of the supply of additional flow to the surface of the water mirror of the initial part of the water supply path;

figure 4 - the same option;

figure 5 - the same option;

6 is the same option;

7 is the same, a variant of one-way discharge, pressureless flow;

Fig - the same, a variant of a two-way discharge, pressureless flow;

Fig.9 is the same, a variant of one-way discharge, pressure flow;

figure 10 is the same, a variant of a two-way discharge, pressure flow;

11 is a variant of supplying an additional flow rate to the surface horizons of the flow of the initial part of the water supply path, one-way discharge, pressure flow;

12 is a variant of supplying an additional flow rate to the surface horizons of the flow of the initial part of the water supply path, two-way discharge, pressure flow;

13 is a variant of supplying additional flow rate to the surface horizons of the flow of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig - option of supplying an additional flow rate to the surface horizons of the flow of the initial part of the water supply path, two-way discharge, pressureless flow;

Fig. 15 is a variant of supplying an additional flow rate to the surface horizons of the flow of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig. 16 is a variant of supplying an additional flow rate to the surface horizons of the flow of the initial part of the water supply path, two-way discharge, pressureless flow;

Fig - option of supplying additional flow at an angle to the longitudinal axis of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig - the same, two-way discharge, pressureless flow;

Fig.19 is a variant of the supply of additional flow at an acute angle to the longitudinal axis in the direction of flow of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig.20 is a variant of the supply of additional flow at an acute angle to the longitudinal axis in the direction of flow of the initial part of the water supply path, two-way discharge, pressureless flow;

21 is a variant of supplying additional flow at an acute angle to the longitudinal axis against the direction of flow in the initial part of the water supply path, one-way discharge, pressureless flow;

Fig. 22 is a variant of supplying additional flow at an acute angle to the longitudinal axis against the direction of flow in the initial part of the water supply path, two-way discharge, pressureless flow;

23 is a variant of supplying an additional flow parallel to the longitudinal axis in the direction of flow in the initial part of the water supply path, pressureless flow;

Fig - option of supplying additional flow into the thickness of the stream of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig - the same, two-way discharge, pressureless flow;

26 is a variant of supplying an additional flow rate into the thickness of the flow of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig - the same, two-way discharge, pressureless flow;

FIG. 28 is a variant of supplying additional flow rate to the bottom horizons of the flow of the initial part of the water supply path, one-way discharge, pressureless flow;

Fig - the same, two-way discharge, pressureless flow;

Fig. 30 is a variant of supplying an additional flow rate to the bottom horizons of the flow of the initial part of the water supply path, parallel to its longitudinal axis and in the direction of flow, pressure flow;

Fig - the same plan;

32 is a variant of supplying additional flow rate to the bottom horizons of the flow of the initial part of the water supply path parallel to its longitudinal axis, against the direction of flow, pressure flow;

Fig. 33 is a variant of supplying an additional flow rate to the surface of the water mirror of the initial part of the water supply path against the direction of flow, pressureless flow;

Fig.34 is the same plan;

Fig. 35 shows a variant of supplying an additional flow rate to the bottom horizons of the flow of the initial part of the water supply path parallel to its longitudinal axis, against the direction of flow, pressure flow, longitudinal section;

Fig - structural solution of the input head of the fish-spawning channel, equipped with fish-guiding devices in the form of bottom curved thresholds, plan;

Fig.37 is a section aa in Fig.36;

Fig.38 is the same, an embodiment of the interface sections of the steps of the tray of the additional power supply unit in the form of planes inclined towards the downstream side;

Fig.39 is a section bB in Fig.36;

Fig - the same, bottom rapids are made with different heights, decreasing towards the downstream;

Fig. 41 is a view B in Fig. 36;

Fig - structural solution of the input part of the fish-spawning channel with an additional power supply of the first and second stage, plan;

Fig. 43 is a section G-G in Fig. 42;

Fig. 44 is the same, showing the hydraulic structure of a fish attracting stream;

Fig. 45 is a variant of supplying an additional flow rate to the surface of the water mirror of the initial part of the water supply path parallel to its longitudinal axis and at an acute angle to the surface of the water, pressure flow;

Fig. 46 is an embodiment of a partition wall curved in plan;

Fig. 47 is an embodiment of a flow guide wall curved in plan and parallel to the dividing wall;

Fig. 48 is an embodiment of a distributing part of perforated pipelines rotatably by means of a drive around its horizontal axis, wherein the pipelines are installed across the water supply path, the rotation drive of the distributing part is mechanical;

49 is a diagram of a mechanical drive in the form of a gear;

Fig. 50 is a cross-sectional view of a dispensing portion of a perforated pipe made rotating;

Fig.51 is the same, an intermediate moment of rotation;

Fig - embodiment of the second stage of an additional power supply in the form of perforated pipelines placed along the water supply path;

Fig.53 is the same, section DD in Fig.52;

Fig. 54 is an embodiment of a second stage of an additional power supply unit in the form of perforated pipelines arranged along the water supply path, the pipelines are made rotating around its horizontal axis, the drive type is mechanical, chain transmission;

55 is a variant of a rotating perforated pipe, the drive type is hydraulic, made in the form of an impeller, rigidly connected to a rotating distributing part of a perforated pipeline, while one end of the pipe is made with a bearing rotating by track rollers resting on a fixed part of the pipeline, and the other pipe end - on a coaxial bearing;

56 is a structural solution of a bearing with track rollers.

Fishery-spawning channel includes a water supply path 1, the channel head of which has an outlet head connected to the upper head of the hydraulic system, and the input head 2 to the lower head of 3, reinforced roughness elements 4 made in the form of parallelepipeds installed on the bottom of the channel along its length at an acute angle to the longitudinal axis of the channel, and an additional power supply 5, the input part of which is connected to the upstream, and the output part 6 with the input tip 2, while the output part 6 of the additional power supply 5 is made in the form of TCA is disposed parallel to the longitudinal axis of the input tip 2 with its outlet opening 7 placed directly in the tray auxiliary power unit 5, and feeding canal path 1 and the additional power supply tray 5 are separated from each other by a partition wall 8.

The dividing wall 8 is made to the entire depth of the flow, the bottom of the tray of the additional power supply unit 5 is made stepwise with a slope towards the downstream 3, and the outlet openings 7 are located at the beginning of each stage 9, while the inlet part 10 of the additional power supply unit 5 is made in the form of a pressure pipe equipped with a flow controller 11, and the end part of the tray of the additional power supply unit 5 freely communicates with the inner space of the water supply path 1, and its initial part is equipped with a flow guide wall 12 installed at an angle to the river flow, while the inlet head 2 is provided with an additional outlet 13 located on the side of the outer surface of the flow guide wall 12 and is located in the surface horizon parallel to its plane, which is connected to the pressure pipe, and the initial section of the water supply path 1 located upstream of the input tip 2, is equipped with a second stage 14 of an additional power supply 5.

In addition, the second stage 14 of the additional power supply 5 can be made in the form of perforated pipelines 15 placed across the water supply path 1.

In addition, the perforation holes 16 can be oriented at an acute angle to the surface of the water.

In addition, the perforation holes 16 can be oriented at an obtuse angle to the surface of the water.

In addition, the input tip 2 can be made with fish-guiding devices in the form of bottom sills 17, while the sills 17 in plan can be made curved and with their convex side facing the separation wall 8.

In addition, the height of the bottom rapids 17 may decrease in the direction of the downstream 3.

In addition, the end parts of the bottom sills 17 can be placed in different transverse sections.

In addition, the dividing wall 8 can be made curved, while its convex surface faces the upstream side.

In addition, the guide wall 12 may be parallel to the partition wall 8.

In addition, the dispensing portion of the perforated conduits 15 may be rotatable by the actuator 18 about its horizontal axis.

In addition, the second stage 14 of the additional power supply 5 can be made in the form of perforated pipelines 15 located along the water supply path 1.

In addition, the drive 18 of the rotation of the distributing part of the perforated pipelines 15 can be made mechanical.

In addition, the drive 18 of the rotation of the distributing part of the perforated pipelines 15 can be made hydraulic.

In addition, the rotation drive 18 of the dispensing part of the perforated pipelines 15 can be made in the form of an impeller 19, rigidly connected to the distributing part and installed in the end part of the supply pipe 10.

In addition, the mating sections of the steps 9 of the tray of the additional power supply 5 are made in the form of planes inclined towards the downstream side.

For spawning of fish directly in the water supply path 1 of the fish passage and spawning canal, its bottom is made with gravel and pebble bedding 0.3 meters thick, which performs the function of spawning substrate 20.

Perforated pipes 15 are located on the overpass 21, placed across the water path 1.

The drive 18, made mechanical, can be connected to a chain gear 22.

In the case of the hydraulic drive, the perforated tube 15 with one end adjacent to the inlet part 10 can be mounted on the track rollers 23.

The method of attracting fish to the input head in the fish-spawning channel is as follows.

The technology of transferring the additional flow rate previously supplied to the inlet head 2 (Fig. 1) directly to the section of the water supply path 1 of the fish-spawning channel located upstream of the inlet head 2 makes it possible to provoke a fish concentrated in front of the inlet head 2 to an active approach directly into the interior of the fish passage tract. This operation increases the efficiency of the entire structure

After the process of stabilizing the boundaries of the fish attracting stream and the conditions for fish to enter the inlet head 2, an additional water flow rate is supplied directly to the section of the water supply path 1 located upstream of the inlet head 2, while the flow of the additional flow rate to the inlet head 2 is simultaneously stopped. 2).

The method can be implemented by the following technology. The supply of additional water flow to the surface of the water mirror (Fig. 3, 4, 5, 6, 7, 8, 9, and 10) allows you to create the most favorable hydraulic conditions for the passage of bottom fish species (for example, sturgeon). At the same time, in the bottom horizons of the flow, the influence of additional masses of flow is almost not felt. In addition, the noise of the water flow incident on the surface of the mirror imitates conditions close to the operating conditions of the spillway dam of the waterworks. Moreover, additional water falling on the surface of the flow mirror allows aeration of the surface layers of the water flow (Figs. 50 and 51).

The method can be implemented by the following technology. The supply of additional water flow to the surface horizons (11, 12, 13, 14, 15, 16) of the water supply path 1 allows us to provide normal conditions for the merger of the two costs - the main (flow fish passage) and additional (flow from the additional power supply 14) . At the same time, in the bottom horizons of the main flow there is practically no effect of additional masses of discharge discharged to the surface horizons of the flow.

The method can be implemented by the following technology. The supply of additional water flow from the power supply unit of the second 14 in the form of dispersed hydraulic jets (Fig.17, 18, 19, 20, 21, 22), oriented at an angle to the longitudinal axis of the water supply path 1, allows to reduce the hydraulic resistance of the main stream and reduce the likelihood of erosion bed of the fish-spawning canal. The method can be implemented by the following technology.

The additional flow of water in the form of dispersed hydraulic jets oriented parallel to the longitudinal axis of the water supply path 1 (Fig.23) also allows you to reduce the hydraulic resistance of the main stream and reduce the likelihood of erosion of the bed of the fish-spawning channel. In addition, this pattern of discharge of the additional flow of water does not disorient the fish as they move along the fish passage.

The method can be implemented by the following technology. The supply of additional water flow into the thickness of the stream (Fig.24, 25, 26 and 27) of the water supply path 1 allows us to provide normal conditions for the merger of two costs - the main (flow fish passage) and additional (flow from the additional power supply 14). At the same time, in the thickness of the stream, the average velocity of the main stream increases, which makes it possible to activate the movement of fish moving in these horizons.

The method can be implemented by the following technology. The supply of additional water flow to the bottom horizons of the flow of the water supply path 1 (Fig. 28, 29, 30 and 35) also allows us to provide normal conditions for the merger of the two costs - the main (flow fish passage) and additional (flow from the additional power supply 14). At the same time, the average velocity of the main stream increases in the bottom horizons of the stream, which makes it possible to activate the movement of fish moving in these horizons (for example, sturgeons). The method can be implemented by the following technology. The flow diagram of the additional flow of water in the direction of the main stream in the water supply path 1 (Fig. 4, 19, 20, 23, 30 and 31) is an option for dumping additional masses of water. In this embodiment, the main stream minimally experiences resistance from the side of the additionally discharged flow. In this case, the velocity values in the vertical and planned diagrams increase.

The method can be implemented by the following technology.

The flow diagram of the additional flow of water against the direction of the main stream in the water supply path 1 (Fig.21, 22, 32, 33, 34 and 35) is an alternative option for dumping additional masses of water. In this embodiment, the main flow experiences additional hydraulic resistance at those flow horizons into which the additional flow of water is discharged. In this case, the values of the velocities in the vertical and planned diagrams in the discharged alignments and horizons decrease. The application of this scheme is possible if it is necessary to create additional water level backwater in the initial part of the fish passage-spawning channel or to create favorable hydraulic conditions for the passage of fish in various horizons of the water passage of the fish passage channel.

Fishery-spawning channel works as follows.

Attraction of fish from the downstream pool 3 to the inlet head 2 of the water supply path 1 is carried out by supplying a working flow from the upstream flowing through the water supply path 1. In addition, due to the operation of the power supply unit 5 along the supply part 10, the working water flow also enters the inlet head 2, which, together with the flow rate of the water supply path 1 forms a fish-attracting “train” of speeds (Fig. 44).

The implementation of the separation wall 8 to the entire depth of the stream allows you to create an autonomous channel in the structure of the inlet head 2, while this channel is designed to form an additional attracting fish stream and allows the fish to move freely from the downstream side 3 in the direction of the water path 1 of the fish spawning channel.

To enhance the allocation of attracting fish flow allows the constant supply of part of the additional flow rate to the outlet 13, made from the outer surface of the flow guide wall 12, which is located in the surface horizon of the stream and parallel to its plane, and the outlet 13 is connected to the pressure pipe of the supply part 10. When feeding a working flow of water from the outlet 13, a plane-parallel hydraulic jet flows, which in the initial stage of its propagation moves l the outer surface of the guide wall 12. This flow of additional water flow allows the dynamic impact of a plane-parallel hydraulic jet on the river flow, as well as due to the active ejection of the surrounding water masses to increase not only the propagation range of the fenders, but also allows you to create stable conditions for the formation of the outer boundary of the fish attracting stream.

Bottom species of fish (for example, sturgeon), moving mainly at the bottom of the watercourse, focusing on the attracting bottom stream, enter the inlet head 2 and then advance to the water supply path 1, where optimal conditions are created for their spawning on the spawning substrate 20. If the conditions created in the water supply path 1, do not satisfy migrants, then they roll into the wellhead part 2 and, without leaving the mouth part 2, are able to move along the water supply path 1 to its outlet head and go to the upper pool, where e continue spawning migration.

To increase the efficiency of migrants' passage from the zone of influence of the input tip 2 directly to the water supply path 1, the operation service performs the following operations with the mechanical equipment of the additional power supply unit 5 (first stage) and the additional power supply unit 14. The flow regulator 11 of the supply part 10 supplying the additional unit 5, cover, at the same time open the flow regulator 11 of the inlet part 10, which feeds the second stage 14 of the additional power supply. As a result, there is a change in the circuits for supplying an additional flow of water - from the initial circuit (Fig. 1) to the auxiliary circuit (Fig. 2). This technology of transferring the additional flow rate previously supplied to the inlet head 2 directly to the section of the water supply path 1 of the fish-spawning channel located upstream of the inlet head 2 makes it possible to provoke a fish concentrated in front of the inlet head 2 to actively enter directly into the internal space fish passage tract.

The supply of additional flow to an additional power supply unit of the second stage 14 may be different and depends on the type of fish passed, their physiological condition, swimming ability of fish of other indicators.

In this particular case, we will consider the layout of an additional power supply unit of the second stage 14, made in the form of perforated pipelines 15, placed across the water supply path 1 (Fig.2 and 43). The additional flow rate to the water mirror allows creating the most favorable hydraulic conditions for the passage of bottom fish species (for example, sturgeon). At the same time, in the bottom horizons of the flow, the influence of additional masses of flow is almost not felt. In addition, the noise of the water flow incident on the surface of the mirror imitates conditions close to the operating conditions of the spillway dam of the waterworks. Moreover, additional water falling on the surface of the flow mirror allows aeration of the surface layers of the water flow (Figs. 50 and 51).

The perforation holes 16 of the perforated pipelines 15, oriented at an acute angle to the surface of the water, can actively aerate the surface layer of the stream, since the dispersed hydraulic jets actively inject the surrounding air and draw it into the surface horizons of the stream. With this arrangement, the acoustic effect arising from the interaction of the jets with the surface of the water is more pronounced.

The perforation holes 16 of the perforated pipelines 15, oriented at an obtuse angle to the surface of the water, also allow you to aerate the surface layer of the stream, since falling drops and jets of water contribute to the process of saturation of the surface horizons of the air with air. However, in this arrangement there are no concentrated jets (streams), which avoids the concentration of surface fish in the discharge zone of the additional flow.

A variant of the operation of the input head 2, equipped with fish guiding devices in the form of bottom sills 17, is possible, while the sills 17 are curved in plan and have their convex side facing dividing wall 8, which not only stabilizes the flow of fish attracting fish in bottom horizons, but also allows stable tactile landmarks, using which bottom fish species (for example, sturgeon) are guaranteed to move in the direction of the waterway 1 (Figs. 36 and 38).

A variant of the operation of the input head 2 is possible, when the height of the bottom rapids 17 is different and decreasing in the direction of the downstream, which enhances the effect of stabilization of the flow in the bottom horizons and, in addition, allows the fish to move in the space bounded by the bottom rapids 17, thereby changing paths of their movements within the input head 2 (Fig.40).

A variant of the operation of the input head 2 is possible, when the end parts of the bottom rapids 17 are located in different transverse sections extended to the river bed, which allows you to form tactile landmarks along the length of the bottom rapids 17. This arrangement allows you to intercept bottom fish at an early stage of their movement in the influence zone fish-guiding devices (Figs. 36 and 42).

The implementation of the separation wall 8 is curved in plan, with its convex surface facing the upstream, allows you to optimize the hydraulic conditions in the influence zone of the inlet head 2, as well as improve the conditions for the movement of fish in the direction of the water path 1. In addition, the curved plane of the separation wall 8 makes it possible to ensure continuous flow around the river in transit with its external lateral surface.

The execution of the guide wall 12 parallel to the separation wall 8 allows you to optimize the hydraulic structure of the fish attracting stream and the conditions for the promotion of fish in the area of their installation.

The execution of the distributing part of the perforated pipelines 15 with the possibility of rotation (Fig. 50 and 51) by means of the actuator 18 around its horizontal axis allows you to quickly change the discharge pattern of the additional flow of water to the surface of the water mirror (for example, the transition from the circuit "perforation holes 16 are oriented at an acute angle water surface "to the pattern" of the perforation holes 16 are oriented at an obtuse angle to the water surface "and vice versa).

The execution of the drive 18 of the rotation of the distributing part of the perforated pipelines 15 mechanical is an embodiment of the actuator 18 (Fig.48, 49 and 54). In addition, the mechanical drive 18 is more reliable than all other types of drive mechanisms.

The execution of the drive 18 of the rotation of the distributing part of the perforated pipelines 15 hydraulic is also an embodiment of the actuator 18. However, in this case, we are able to use the kinetic energy of the water flow supplied to the perforated pipelines 15.

The execution of the drive 18 of the rotation of the distributing part of the perforated pipelines 15 in the form of an impeller 19, rigidly connected to the distributing part and installed in the end part of the supply pipe, is a special case of a hydraulic drive (Fig. 55).

The execution of the pairing sections of the steps 9 of the tray of the additional power supply 5 in the form of planes inclined toward the downstream 3 allows to optimize the process of moving bottom fish in the bottom of the autonomous tray (Fig. 38).

The proposed layout of the input head is equipped with all the necessary tools that provide stable and efficient conditions for the formation of a stream attracting fish.

Information sources

1. USSR author's certificate No. 1666633, "Fish-breeding and spawning canal", E 02 B 8/08, Authors: Shkura VN, Chistyakov AA, Novadarsky AV, Anokhin AM and Cherkasov V.A. (THE USSR). Publ. BI №28, 1991

2. A.S. USSR No. 1544879, MKI E 02 V 8/08 Fish Passage / Skura V.N., Sukalo G.M., Guyumdzhibashyan A.G., and Anikin B.C. (THE USSR). Publ. BI No. 7, 1990.

Claims (25)

1. The method of attracting fish to the inlet head of the fish-spawning channel, which consists in creating a fish-attracting stream in the alignment of the inlet head by supplying an attracting flow rate from the water supply path and an additional power supply to the inlet head, and a stable hydraulic structure is formed in the zone of influence of the inlet head and against the background of the search zone for fish, characterized in that after the stabilization of the boundaries of the flow attracting fish and the conditions for fish to enter the inlet head, an additional p The water flow is fed directly to the section of the water supply path located upstream of the inlet head, while at the same time the supply of additional flow to the inlet head is cut off. 2. The method according to p. 1, characterized in that the additional flow of water to the section of the water supply path located upstream of the inlet head is fed to the surface of the water mirror. 3. The method according to p. 1, characterized in that the additional flow of water to the section of the water supply path located upstream of the inlet head is fed to surface horizons. 4. The method according to p. 3, characterized in that the additional flow of water is served by dispersed hydraulic jets oriented at an angle to the longitudinal axis of the water supply path. 5. The method according to p. 3, characterized in that the additional flow of water is served by dispersed hydraulic jets oriented parallel to the longitudinal axis of the water supply path. 6. The method according to p. 1, characterized in that the additional flow of water to the section of the water supply path located upstream of the inlet head is fed into the thickness of the stream. 7. The method according to p. 1, characterized in that the additional flow of water to the section of the water supply path located upstream of the inlet head is fed to the bottom horizons of the stream. 8. The method according to any one of paragraphs. 3 to 7, characterized in that the additional flow of water is fed in the direction of the main stream in the water path. 9. The method according to any one of paragraphs. 3 to 7, characterized in that the additional flow of water is fed against the direction of the main stream in the water path. 10. Fishery-spawning canal, including a water supply path made in the form of a canal, the output head of which is connected to the upper pool of the hydraulic system, and the input head is connected to the lower pool, reinforced roughness elements made in the form of parallelepipeds installed on the bottom of the channel along its length under an acute angle to the longitudinal axis of the channel, and an additional power supply unit, the input part of which is connected to the upstream, and the output part - with the input head, while the output part of the additional power supply is made in the form of a tray located parallel to the longitudinal axis of the inlet head, and its outlet openings are located directly in the tray of the additional power supply unit, and the water supply path and the tray of the additional power supply unit are separated from each other by a separation wall, characterized in that the separation wall is made to the entire depth of the stream, the bottom of the additional tray the power supply is made stepwise with a bias towards the downstream, and the outlet holes are located at the beginning of each stage, while the supply part of the additional the power supply unit is made in the form of a pressure pipe equipped with a flow regulator, and the end part of the tray of the additional power supply unit is freely connected with the internal space of the water supply path, and its initial part is equipped with a directional wall mounted at an angle to the river transit flow, while the inlet head is equipped with an additional outlet a hole located on the side of the outer surface of the guide wall and located in the surface horizon parallel to its plane, to ond is connected to the feed line, the initial section of the water-path disposed upstream from the inlet tip is provided with an additional second power supply queue. 11. Fishery and spawning channel according to claim 10, characterized in that the second stage of the additional power supply unit is made in the form of perforated pipelines placed across the water supply path. 12. Fishery and spawning canal according to claim 11, characterized in that the perforation holes are oriented at an acute angle to the surface of the water. 13. Fishery-spawning channel according to claim 11, characterized in that the perforation holes are oriented at an obtuse angle to the water surface. 14. Fishery and spawning canal according to claim 10, characterized in that the inlet head is made with fish guiding devices in the form of bottom sills, while the sills are curved in plan and have their convex side facing the dividing wall. 15. Fishery and spawning canal according to claim 14, characterized in that the height of the bottom rapids decreases in the direction of the downstream. 16. Fishery and spawning canal according to claim 14, characterized in that the end parts of the bottom sills are located in different transverse sections. 17. Fishery and spawning channel according to any one of paragraphs. 10 to 16, characterized in that the dividing wall is made curved, while its convex surface faces the upstream. 18. Fishery and spawning channel according to any one of paragraphs. 10 to 16, characterized in that the flow guide wall is made parallel to the dividing wall. 19. Fishery and spawning channel according to claim 11, characterized in that the distributing part of the perforated pipelines is rotatable by means of a drive around its horizontal axis. 20. Fishery and spawning canal according to claim 10, characterized in that the second stage of the additional power supply unit is made in the form of perforated pipelines placed along the water supply path. 21. Fishery-spawning channel according to claim 20, characterized in that the distributing part of the perforated pipelines is rotatable by means of a drive around its horizontal axis. 22. Fishery and spawning channel according to claim 19 or 21, characterized in that the rotation drive of the dispensing part of the perforated pipelines is mechanical. 23. Fishery and spawning channel according to claim 19 or 21, characterized in that the rotation drive of the dispensing part of the perforated pipelines is made hydraulic. 24. Fishery-spawning channel according to claim 23, characterized in that the rotation drive of the dispensing part of the perforated pipelines is made in the form of an impeller rigidly connected to the distributing part and installed in the end part of the supply pipe. 25. Fishery and spawning channel according to any one of paragraphs. 10 to 16, characterized in that the mating sections of the steps of the tray of the additional power supply unit are made in the form of planes inclined towards the downstream side.

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